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Tall buildings
Florea Dinu Lecture 13: 25/02/2014 European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
520121-1-2011-1-CZ-ERA MUNDUS-EMMC
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings
Part II – Multistorey buildings
• Tall buildings, History, Systems, Peculiarity of design, New developments
Tall buildings • Multistory buildings
– Tall buildings has always fascinated people – The construction techniques, both for infrastructure and
suprastructure, changed during the time • A building can be considered as tall when the effect of lateral loads is
reflected in the design • It is important to take into account the effects of dead, live, wind as well
as seismic loads • In order to achieve a good performance under these loads, lateral
deflections and accelerations should be limited
Old Walled City of Shibam, Yemen Most of the city's houses come mainly from the 16th century. Shibam is often called "the oldest skyscraper-city in the world“. Buildings reach 40 m height.
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 3
• A tall building boom in the late 1920s and early 1930s in urban centers Chicago and New York • Home Insurance Building
located in Chicago (1885) - 12 stories tall with a height of 55 m (cast iron), is considered the first skyscraper
• 1930, the Chrysler Building in New York became the world’s tallest,
• the Empire State Building - completed in April 1931 (built in one year and 45 days), at 382 m, surpassed the Chrysler Building by 62.2 m
Home Insurance Building
Drawing from Fortune Magazine, September 1930, Skyscraper Comparison
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 4
The evolution of New York City’s skyline from 1879 to 2013
http://workattheyard.com/the-evolution-of-the-new-york-city-skyline/
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 5
Evolution of tall buildings • Multi-storey frame buildings
– Skyscrapers also began to appear in other parts of the world (Mexico City, Tokyo, Shanghai, Hong Kong, Singapore, Kuala Lumpur, Taipei, Jakarta, etc.).
– Modern multistory buildings use steel for the main structural members (or in combination with concrete – composite structure)
– Despite the recent events that threatened the construction of very tall buildings, their developments have been continuously increasing worldwide.
– Many tall buildings were recently completed or are going to be completed in the near future – Dubai has 18 completed buildings that rise at least 300 metres !!!!!! This includes the tallest man made structure Burj Khalifa
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 6
Dubai, 1990
Dubai, 2003
Dubai, 2007
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 7
Burj Dubai: 818m Present development
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 8
Challenges and uncertainties
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 9
Challenges and uncertainties • Cost
– initial costs – operational costs – dismantling
• Design and erection – new design methodologies (PBD) – new systems, materials,
technologies • Sustainability (“Green” or “sustainable”
buildings) – Life Cycle Assessment – Energy use – Emissions from energy – Water use – Waste reduction – Productivity and health
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 10
• A rigid unbraced frame may be capable of resisting lateral loads without relying on an additional bracing system in case of a low to medium-height building
• High-rise building systems should use structural systems that are effective in resisting the larger lateral loads
• Types of lateral-load resisting systems (R. Plank, M. McEvoy): – Shear frames: beams and columns connected with rigid joints – Shear truss: bracing between columns to form vertical shear trusses – Shear truss-frames: shear frames + shear trusses – Shear truss-frame-outrigger and belt trusses: internal core is connected to
perimeter frames by deep girders – outriggers. – Framed tubes: close spacing columns on the exterior frames forming a vertical
tube. The tube behaves as a cantilever – Truss tubes: the same system as framed tubes, tied by a system of diagonals – Bundled or modular tubes: framed or trusses tubes grouped together like cells – Super-frame: megaframe in the overall form of a Vierendeel frame – Composite systems: mixed RC and steel systems (concrete shear walls or
concrete framed tubes combined with various structural steel framings • Recommended limits for typical multistory frames are given in
the next table
Lateral-load resisting systems
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 11
Steel systems
Lever House building, New York, 1952
Chicago Civic Center Building, 1965
First Wisconsin Center Building, 1974 WTC Building, 1972
Sears Towers Building, Chicago, 1974 John Hancock Center building, Chicago, 1969
But
tress
ed c
ore
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 12
Hongkong and Shanghai Bank Completed 1986 180 meters height
Structural systems for multistory buildings
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 13
Structural systems • Even for high seismic areas,
for buildings with more then 25-30 stories, the wind load becomes predominant in design
• However, seismic design philosophy should taken into account (structural system, local detailing, ….)
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 14
Outrigger and belt truss system � The outriggers couple the columns and
the core � The lateral deflections are smaller than if
the core is freestanding � Belt trusses around the building
� Reduce building deflections and core bending stresses � Reduce the rotational reactions � Minimize the structural cost penalty associated with stability
of slender buildings � Effective for improving 3D behavior of irregular buildings
Advantages:
Braced core
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 15
Optimum location of belt and outrigger trusses: a) one outrigger; b) two outriggers;
c) three outriggers; d) for outriggers
Note:
Deflection index = Top displacement with/without outriggers
Top displacement with outriggers
Deflection index vs. level of the outrigger
Outriggers and belt trusses at several locations
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 16
Tube building with diagonals • Structures with closely columns (tube) and perimetral
bracings
a) Tube building with diagonals on multiple stories; b) Building with rotated tubes and super diagonals
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 17
Tube effect • Structures with closely spaced columns and deep
spandrels (tube effect)
Columns have major axis on
perimeter direction
Isometric view of framed tube Schematic plan of framed tube
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 18
Important: distribution of axial stresses in the square tube with/without “shear lag” effect
“Shear lag” effect in the tube. Important: distribution of axial stresses is different comparing to classical bending theory
Shear lag effect
Bending effect and “shear lag” in case of a tube with free transversal displacement
Bending effect and “shear lag” in case of a tube with closely spaced columns
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 19
Multiple tubes • Structures with multiple tubes
Concept of a structure with multiple tubes: a) perimetral diagonal bracings; b) X bracings and moment connected spandrels; c) perimeter moment connected frames
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 20
Willis Tower (formerly Sears Tower), Chicago, Illinois
Better distribution of stresses due to bundled cross section (smaller
shear lag)
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 21
Trend: steel composite high-strength concrete and steel combination
Taipei 101, 448 m (2003) 8 compos. mega-col. + core 16 comp. col.
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 22
• Strong winds may cause a variety of problems, particularly in tall buildings • Modern tall buildings are even more prone to wind action, due to their lightweight walls and partitions, which reduce the mass and the damping • Even for high seismic areas, for buildings with more then 25-30 stories, the wind load governs the design • Attention should be paid to the following criteria: – Strength and stability – Fatigue of members and connections – Excessive lateral deformations (may cause cracking of claddings or permanent deformations to nonstructural elements) – Excessive vibrations that cause discomfort to the occupants
Wind load Wind load vs. seismic load
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 23
Wind load
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 24
Influence of extreme height to building frame
In addition to usual checks: 1. Dynamic effects of wind. 2. P - ∆ effect (2nd order effect). 3. Influence of member shortening. 4. Static and dynamic rigidity: δmax ≤ H/500 acceleration a ≤ amax ≈ 0,015 g 5. Interaction with ground (especially if H/B > 5).
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 25
Dynamic effects of wind Generally: • analysis including vibration: - longitudinal (in the wind direction) - lateral (in transversal direction): circular, elliptic shapes: "vortex shedding" rectangular shapes: "galloping" (occurs rarely) Vortex shedding, vortex separation (called also Karman periodic set of whirlwinds) results on condition that:
The first frequency of a building: n ≈ 46/h Strouhal number: circle St = 0,18
Rearrangement of the building shape wind tunnel, each variation is significant.
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 26
Longitudinal dynamic wind effects
Wind loading for area Aref according to EN 1993-1-4: - if h ≤ 100 m and b > 30 m, coefficient of the structure cscd = 1; - otherwise use „detailed method" (depends on natural frequency n , parameters of wind and structure ...) - Eurocode enables to determine even deflection and vibration acceleration
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 27
P - ∆ effect (2nd order effect) Represents effect of horizontal shift on internal forces. Solution:
• 2nd order theory (or geometrically nonlinear analysis GNA), • or approximately (see also determination of αcr in global analysis):
If SLS is fulfilled, the approximate guess of V, H (for all building or floor) gives coefficient of 2nd order m. The horizontal loading then multiply with m:
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 28
Influence of member shortening The shortening of member axes is covered by computer FEM analysis!
The stress in diagonals from vertical loading is, therefore, of the same order as in columns! Measures: - final connection of diagonals not until assembly of all building, - or prestressing of diagonals to eliminate compression due to vertical loading.
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 29
• Many of European areas are under seismic risk • Southern Europe experienced very damaging earthquakes
during the last decades. • Many existing structures have inadequate protection against
strong earthquakes. The vulnerability is very much increasing, due to the rapid grow of the construction industry.
• Seismic loading requires an understanding of the structural behavior under inelastic cyclic deformations
• Behavior under such loading is fundamentally different from wind loading (and gravity loading). It is necessary to pay more attention to type of analysis and detailing requirements, in order to assure acceptable seismic performance beyond the elastic range.
• Some structural damage in members and connections can be expected under design ground motion, as the majority of modern seismic codes allow inelastic energy dissipation in the structural system
Seismic load
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 30
– Soil may act as a filter
– It can modify frequency content of the ground motion
– Amplification of the ground motion (or reduction) may be recorded on site
– Duration of the ground motion is increased
Local effects on site
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 31
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 32
1985 Mexico City - Pino Suarez
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
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1989 Loma Prieta
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
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Sustainable Constructions under Natural Hazards and Catastrophic Events
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Effect of damping • Structural response may be reduced by an increase of
the damping properties • Damping of the structural elements is limited • One option for increasing the damping is the introduction
of external damping devices – Viscoelastic passive dampers – Passive control (tuned mass dampers) – Active control (tuned active dampers)
• These systems are effective both against winds and earthquakes
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
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Yokohama Landmark Tower, 295.8 m Tuned active dampers
Reduction of the acceleration: 29% ÷ 39%
Tuned mass dampers Viscoelastic passive dampers
World Trade Center, 417 m
10 000 dampers in the structure, about 100 dampers at the ends of the floor trusses at each floor from the 7th to the 107th
Burj al Arab, Dubai, 321 m Taipei 101 , 509.2 m
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 36
– Buckling-restrained braced frames (BRB)
– Steel plate shear walls (SPSW)
– Systems with removable dissipative members (RDM)
New structural systems for seismic applications
Schematic and typical types of buckling restrained braces
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 37
Application of BRB - Tzu-Chi Culture Building, Taiwan
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
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• The Steel Plate Shear Walls (SPSWs) application has increased in recent years. Design requirements for SPSWs are already implemented in the AISC 2005.
• One of the most important application of steel plate shear walls in a very highly seismic area is the 35-story high-rise in Kobe, Japan.
• The structure was constructed in 1988 and was subjected to the 1995 Kobe earthquake.
Steel plate shear walls
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
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• Studies of this structure (Fujitani et al., 1996) (AIJ, 1995) have indicated that the damage was minor and consisted of local buckling of stiffened steel plate shear walls on the 26th story (Fujitani et al., 1996)
• Interesting to note the adjacent building was heavily damaged during the same earthquake, suffering a partial collapse due to a soft story mechanism
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 40
Seismic intensity map
Corner period
L10 – B.2 – Mechanical properties of cast iron, mild iron and steel at historical structures
European Erasmus Mundus Master Course
Sustainable Constructions under Natural Hazards and Catastrophic Events
L13 - 2C08 Tall buildings 41
This lecture was prepared for the 1st Edition of SUSCOS (2012/14) by Prof. Josef Macháček (CTU) and Michal
Jandera, PhD. (CTU).
Adaptations brought by Florea Dinu, PhD (UPT) for 2nd Edition of SUSCOS
The SUSCOS powerpoints are covered by copyright and are for the exclusive use by the SUSCOS teachers in the framework of this Erasmus
Mundus Master. They may be improved by the various teachers throughout the different editions.
florea.dinu@upt.ro
http://steel.fsv.cvut.cz/suscos
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